The first line simply tells that the source code is written for
Solidity version 0.4.0 or anything newer that does not break functionality
(up to, but not including, version 0.5.0). This is to ensure that the
contract does not suddenly behave differently with a new compiler version. The keyword pragma is called that way because, in general,
pragmas are instructions for the compiler about how to treat the
source code (e.g. pragma once).

A contract in the sense of Solidity is a collection of code (its functions) and
data (its state) that resides at a specific address on the Ethereum
blockchain. The line uintstoredData; declares a state variable called storedData of
type uint (unsigned integer of 256 bits). You can think of it as a single slot
in a database that can be queried and altered by calling functions of the
code that manages the database. In the case of Ethereum, this is always the owning
contract. And in this case, the functions set and get can be used to modify
or retrieve the value of the variable.

To access a state variable, you do not need the prefix this. as is common in
other languages.

This contract does not do much yet (due to the infrastructure
built by Ethereum) apart from allowing anyone to store a single number that is accessible by
anyone in the world without a (feasible) way to prevent you from publishing
this number. Of course, anyone could just call set again with a different value
and overwrite your number, but the number will still be stored in the history
of the blockchain. Later, we will see how you can impose access restrictions
so that only you can alter the number.

Note

All identifiers (contract names, function names and variable names) are restricted to
the ASCII character set. It is possible to store UTF-8 encoded data in string variables.

Warning

Be careful with using Unicode text as similarly looking (or even identical) characters can
have different code points and as such will be encoded as a different byte array.

The following contract will implement the simplest form of a
cryptocurrency. It is possible to generate coins out of thin air, but
only the person that created the contract will be able to do that (it is trivial
to implement a different issuance scheme).
Furthermore, anyone can send coins to each other without any need for
registering with username and password - all you need is an Ethereum keypair.

pragmasolidity^0.4.0;contractCoin{// The keyword "public" makes those variables// readable from outside.addresspublicminter;mapping(address=>uint)publicbalances;// Events allow light clients to react on// changes efficiently.eventSent(addressfrom,addressto,uintamount);// This is the constructor whose code is// run only when the contract is created.functionCoin()public{minter=msg.sender;}functionmint(addressreceiver,uintamount)public{if(msg.sender!=minter)return;balances[receiver]+=amount;}functionsend(addressreceiver,uintamount)public{if(balances[msg.sender]<amount)return;balances[msg.sender]-=amount;balances[receiver]+=amount;Sent(msg.sender,receiver,amount);}}

This contract introduces some new concepts, let us go through them one by one.

The line addresspublicminter; declares a state variable of type address
that is publicly accessible. The address type is a 160-bit value
that does not allow any arithmetic operations. It is suitable for
storing addresses of contracts or keypairs belonging to external
persons. The keyword public automatically generates a function that
allows you to access the current value of the state variable.
Without this keyword, other contracts have no way to access the variable.
The function will look something like this:

functionminter()returns(address){returnminter;}

Of course, adding a function exactly like that will not work
because we would have a
function and a state variable with the same name, but hopefully, you
get the idea - the compiler figures that out for you.

The next line, mapping(address=>uint)publicbalances; also
creates a public state variable, but it is a more complex datatype.
The type maps addresses to unsigned integers.
Mappings can be seen as hash tables which are
virtually initialized such that every possible key exists and is mapped to a
value whose byte-representation is all zeros. This analogy does not go
too far, though, as it is neither possible to obtain a list of all keys of
a mapping, nor a list of all values. So either keep in mind (or
better, keep a list or use a more advanced data type) what you
added to the mapping or use it in a context where this is not needed,
like this one. The getter function created by the public keyword
is a bit more complex in this case. It roughly looks like the
following:

As you see, you can use this function to easily query the balance of a
single account.

The line eventSent(addressfrom,addressto,uintamount); declares
a so-called “event” which is fired in the last line of the function
send. User interfaces (as well as server applications of course) can
listen for those events being fired on the blockchain without much
cost. As soon as it is fired, the listener will also receive the
arguments from, to and amount, which makes it easy to track
transactions. In order to listen for this event, you would use

Coin.Sent().watch({},'',function(error,result){if(!error){console.log("Coin transfer: "+result.args.amount+" coins were sent from "+result.args.from+" to "+result.args.to+".");console.log("Balances now:\n"+"Sender: "+Coin.balances.call(result.args.from)+"Receiver: "+Coin.balances.call(result.args.to));}})

Note how the automatically generated function balances is called from
the user interface.

The special function Coin is the
constructor which is run during creation of the contract and
cannot be called afterwards. It permanently stores the address of the person creating the
contract: msg (together with tx and block) is a magic global variable that
contains some properties which allow access to the blockchain. msg.sender is
always the address where the current (external) function call came from.

Finally, the functions that will actually end up with the contract and can be called
by users and contracts alike are mint and send.
If mint is called by anyone except the account that created the contract,
nothing will happen. On the other hand, send can be used by anyone (who already
has some of these coins) to send coins to anyone else. Note that if you use
this contract to send coins to an address, you will not see anything when you
look at that address on a blockchain explorer, because the fact that you sent
coins and the changed balances are only stored in the data storage of this
particular coin contract. By the use of events it is relatively easy to create
a “blockchain explorer” that tracks transactions and balances of your new coin.

Blockchains as a concept are not too hard to understand for programmers. The reason is that
most of the complications (mining, hashing, elliptic-curve cryptography, peer-to-peer networks, etc.)
are just there to provide a certain set of features and promises. Once you accept these
features as given, you do not have to worry about the underlying technology - or do you have
to know how Amazon’s AWS works internally in order to use it?

A blockchain is a globally shared, transactional database.
This means that everyone can read entries in the database just by participating in the network.
If you want to change something in the database, you have to create a so-called transaction
which has to be accepted by all others.
The word transaction implies that the change you want to make (assume you want to change
two values at the same time) is either not done at all or completely applied. Furthermore,
while your transaction is applied to the database, no other transaction can alter it.

As an example, imagine a table that lists the balances of all accounts in an
electronic currency. If a transfer from one account to another is requested,
the transactional nature of the database ensures that if the amount is
subtracted from one account, it is always added to the other account. If due
to whatever reason, adding the amount to the target account is not possible,
the source account is also not modified.

Furthermore, a transaction is always cryptographically signed by the sender (creator).
This makes it straightforward to guard access to specific modifications of the
database. In the example of the electronic currency, a simple check ensures that
only the person holding the keys to the account can transfer money from it.

One major obstacle to overcome is what, in Bitcoin terms, is called a “double-spend attack”:
What happens if two transactions exist in the network that both want to empty an account,
a so-called conflict?

The abstract answer to this is that you do not have to care. An order of the transactions
will be selected for you, the transactions will be bundled into what is called a “block”
and then they will be executed and distributed among all participating nodes.
If two transactions contradict each other, the one that ends up being second will
be rejected and not become part of the block.

These blocks form a linear sequence in time and that is where the word “blockchain”
derives from. Blocks are added to the chain in rather regular intervals - for
Ethereum this is roughly every 17 seconds.

As part of the “order selection mechanism” (which is called “mining”) it may happen that
blocks are reverted from time to time, but only at the “tip” of the chain. The more
blocks that are added on top, the less likely it is. So it might be that your transactions
are reverted and even removed from the blockchain, but the longer you wait, the less
likely it will be.

The Ethereum Virtual Machine or EVM is the runtime environment
for smart contracts in Ethereum. It is not only sandboxed but
actually completely isolated, which means that code running
inside the EVM has no access to network, filesystem or other processes.
Smart contracts even have limited access to other smart contracts.

There are two kinds of accounts in Ethereum which share the same
address space: External accounts that are controlled by
public-private key pairs (i.e. humans) and contract accounts which are
controlled by the code stored together with the account.

The address of an external account is determined from
the public key while the address of a contract is
determined at the time the contract is created
(it is derived from the creator address and the number
of transactions sent from that address, the so-called “nonce”).

Regardless of whether or not the account stores code, the two types are
treated equally by the EVM.

Every account has a persistent key-value store mapping 256-bit words to 256-bit
words called storage.

Furthermore, every account has a balance in
Ether (in “Wei” to be exact) which can be modified by sending transactions that
include Ether.

A transaction is a message that is sent from one account to another
account (which might be the same or the special zero-account, see below).
It can include binary data (its payload) and Ether.

If the target account contains code, that code is executed and
the payload is provided as input data.

If the target account is the zero-account (the account with the
address 0), the transaction creates a new contract.
As already mentioned, the address of that contract is not
the zero address but an address derived from the sender and
its number of transactions sent (the “nonce”). The payload
of such a contract creation transaction is taken to be
EVM bytecode and executed. The output of this execution is
permanently stored as the code of the contract.
This means that in order to create a contract, you do not
send the actual code of the contract, but in fact code that
returns that code.

Upon creation, each transaction is charged with a certain amount of gas,
whose purpose is to limit the amount of work that is needed to execute
the transaction and to pay for this execution. While the EVM executes the
transaction, the gas is gradually depleted according to specific rules.

The gas price is a value set by the creator of the transaction, who
has to pay gas_price*gas up front from the sending account.
If some gas is left after the execution, it is refunded in the same way.

If the gas is used up at any point (i.e. it is negative),
an out-of-gas exception is triggered, which reverts all modifications
made to the state in the current call frame.

Each account has a persistent memory area which is called storage.
Storage is a key-value store that maps 256-bit words to 256-bit words.
It is not possible to enumerate storage from within a contract
and it is comparatively costly to read and even more so, to modify
storage. A contract can neither read nor write to any storage apart
from its own.

The second memory area is called memory, of which a contract obtains
a freshly cleared instance for each message call. Memory is linear and can be
addressed at byte level, but reads are limited to a width of 256 bits, while writes
can be either 8 bits or 256 bits wide. Memory is expanded by a word (256-bit), when
accessing (either reading or writing) a previously untouched memory word (ie. any offset
within a word). At the time of expansion, the cost in gas must be paid. Memory is more
costly the larger it grows (it scales quadratically).

The EVM is not a register machine but a stack machine, so all
computations are performed on an area called the stack. It has a maximum size of
1024 elements and contains words of 256 bits. Access to the stack is
limited to the top end in the following way:
It is possible to copy one of
the topmost 16 elements to the top of the stack or swap the
topmost element with one of the 16 elements below it.
All other operations take the topmost two (or one, or more, depending on
the operation) elements from the stack and push the result onto the stack.
Of course it is possible to move stack elements to storage or memory,
but it is not possible to just access arbitrary elements deeper in the stack
without first removing the top of the stack.

The instruction set of the EVM is kept minimal in order to avoid
incorrect implementations which could cause consensus problems.
All instructions operate on the basic data type, 256-bit words.
The usual arithmetic, bit, logical and comparison operations are present.
Conditional and unconditional jumps are possible. Furthermore,
contracts can access relevant properties of the current block
like its number and timestamp.

Contracts can call other contracts or send Ether to non-contract
accounts by the means of message calls. Message calls are similar
to transactions, in that they have a source, a target, data payload,
Ether, gas and return data. In fact, every transaction consists of
a top-level message call which in turn can create further message calls.

A contract can decide how much of its remaining gas should be sent
with the inner message call and how much it wants to retain.
If an out-of-gas exception happens in the inner call (or any
other exception), this will be signalled by an error value put onto the stack.
In this case, only the gas sent together with the call is used up.
In Solidity, the calling contract causes a manual exception by default in
such situations, so that exceptions “bubble up” the call stack.

As already said, the called contract (which can be the same as the caller)
will receive a freshly cleared instance of memory and has access to the
call payload - which will be provided in a separate area called the calldata.
After it has finished execution, it can return data which will be stored at
a location in the caller’s memory preallocated by the caller.

Calls are limited to a depth of 1024, which means that for more complex
operations, loops should be preferred over recursive calls.

There exists a special variant of a message call, named delegatecall
which is identical to a message call apart from the fact that
the code at the target address is executed in the context of the calling
contract and msg.sender and msg.value do not change their values.

This means that a contract can dynamically load code from a different
address at runtime. Storage, current address and balance still
refer to the calling contract, only the code is taken from the called address.

This makes it possible to implement the “library” feature in Solidity:
Reusable library code that can be applied to a contract’s storage, e.g. in
order to implement a complex data structure.

It is possible to store data in a specially indexed data structure
that maps all the way up to the block level. This feature called logs
is used by Solidity in order to implement events.
Contracts cannot access log data after it has been created, but they
can be efficiently accessed from outside the blockchain.
Since some part of the log data is stored in bloom filters, it is
possible to search for this data in an efficient and cryptographically
secure way, so network peers that do not download the whole blockchain
(“light clients”) can still find these logs.

Contracts can even create other contracts using a special opcode (i.e.
they do not simply call the zero address). The only difference between
these create calls and normal message calls is that the payload data is
executed and the result stored as code and the caller / creator
receives the address of the new contract on the stack.

The only possibility that code is removed from the blockchain is
when a contract at that address performs the selfdestruct operation.
The remaining Ether stored at that address is sent to a designated
target and then the storage and code is removed from the state.

Warning

Even if a contract’s code does not contain a call to selfdestruct,
it can still perform that operation using delegatecall or callcode.

Note

The pruning of old contracts may or may not be implemented by Ethereum
clients. Additionally, archive nodes could choose to keep the contract storage
and code indefinitely.